U.S. patent number 9,042,337 [Application Number 14/248,243] was granted by the patent office on 2015-05-26 for method and system for multi-carrier packet communication with reduced overhead.
This patent grant is currently assigned to Neocific, Inc.. The grantee listed for this patent is Neocific, Inc.. Invention is credited to Haiming Huang, Xiaodong Li, Titus Lo, Ruifeng Wang.
United States Patent |
9,042,337 |
Li , et al. |
May 26, 2015 |
**Please see images for:
( Certificate of Correction ) ** |
Method and system for multi-carrier packet communication with
reduced overhead
Abstract
A method and system for minimizing the control overhead in a
multi-carrier wireless communication network that utilizes a
time-frequency resource is disclosed. In some embodiments, one or
more zones in the time-frequency resource are designated for
particular applications, such as a zone dedicated for voice-over-IP
(VoIP) applications. By grouping applications of a similar type
together within a zone, a reduction in the number of bits necessary
for mapping a packet stream to a portion of the time-frequency
resource can be achieved. In some embodiments, modular coding
schemes associated with the packet streams may be selected that
further reduce the amount of necessary control information. In some
embodiments, packets may be classified for transmission in
accordance with application type, QoS parameters, and other
properties. In some embodiments, improved control messages may be
constructed to facilitate the control process and minimize
associated overhead.
Inventors: |
Li; Xiaodong (Kirkland, WA),
Huang; Haiming (Bellevue, WA), Lo; Titus (Bellevue,
WA), Wang; Ruifeng (Sammamish, WA) |
Applicant: |
Name |
City |
State |
Country |
Type |
Neocific, Inc. |
Bellevue |
WA |
US |
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Assignee: |
Neocific, Inc. (Bellevue,
WA)
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Family
ID: |
44559912 |
Appl.
No.: |
14/248,243 |
Filed: |
April 8, 2014 |
Prior Publication Data
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Document
Identifier |
Publication Date |
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US 20140219239 A1 |
Aug 7, 2014 |
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Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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13115055 |
Apr 8, 2014 |
8693430 |
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11908257 |
May 24, 2011 |
7948944 |
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PCT/US2006/038149 |
Sep 28, 2006 |
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60721451 |
Sep 28, 2005 |
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Current U.S.
Class: |
370/330 |
Current CPC
Class: |
H04L
5/006 (20130101); H04L 5/0044 (20130101); H04L
1/0029 (20130101); H04J 11/005 (20130101); H04L
5/0053 (20130101); H04L 1/0003 (20130101); H04W
52/146 (20130101); H04L 5/0007 (20130101); H04W
72/048 (20130101); H04L 27/2601 (20130101); H04W
72/04 (20130101); H04L 1/0009 (20130101); H04L
5/0094 (20130101) |
Current International
Class: |
H04W
72/04 (20090101) |
References Cited
[Referenced By]
U.S. Patent Documents
Other References
International Search Report and Written Opinion, International
Patent Application No. PCT/US06/38149; Filed Sep. 28, 2006;
Applicant Neocific, Inc.; Mailed Feb. 21, 2007; 8 pages. cited by
applicant .
Non Final Office Action for U.S. Appl. No. 13/115,055, Mailing
Date: Apr. 29, 2013, 15 pages. cited by applicant .
Notice of Allowance for U.S. Appl. No. 13/115,055, Mail Date Jan.
15, 2014, 9 pages. cited by applicant .
Notice of Allowance for U.S. Appl. No. 13/631,735, Mail Date Nov.
27, 2013, 15 pages. cited by applicant.
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Primary Examiner: Patel; Chandrahas
Attorney, Agent or Firm: Perkins Coie LLP
Parent Case Text
CROSS-REFERENCE TO RELATED APPLICATION(S)
This application is a continuation of, and incorporates by
reference in its entirety, U.S. patent application Ser. No.
13/115,055, filed on May 24, 2011, now U.S. Pat. No. 8,693,430,
which is a continuation of U.S. patent application Ser. No.
11/908,257, filed on Jul. 14, 2008, now U.S. Pat. No. 7,948,944,
which is a national stage application of PCT/US06/38149, filed Sep.
28, 2006, which claims the benefit of U.S. Provisional Patent
Application No. 60/721,451, filed on Sep. 28, 2005.
This application is related to, and incorporates by reference in
its entirety, U.S. patent application Ser. No. 13/631,735, filed on
Sep. 28, 2012, now U.S. Pat. No. 8,634,376.
Claims
We claim:
1. A method for a base station in a multi-cell wireless packet
system using a frame structure, each frame comprising a plurality
of time slots, each time slot comprising a plurality of orthogonal
frequency division multiplexing (OFDM) symbols, the method
comprising: designating a first zone of time-frequency resource in
a cell for transmission of packets associated with a voice
application, the first zone selected to be different from a second
zone of time-frequency resource designated in a neighboring cell
for transmission of packets associated with the voice application;
allocating N basic time-frequency resource units in the first zone
for transmission of a packet associated with the voice application
to a mobile device, wherein a basic time-frequency resource unit
contains a number of subcarriers in a number of OFDM symbols and N
is an integer number; and transmitting a signal carrying the packet
to a mobile device over the N basic time-frequency units in the
first zone.
2. The method of claim 1, wherein the packet contains data
associated with a real time protocol (RTP).
3. The method of claim 2, wherein the data is identified for
transmission in the first zone based on a RTP header associated
with the data.
4. The method of claim 1, wherein the packet contains data
associated with a user datagram protocol (UDP).
5. The method of claim 1, wherein the packet contains data
associated with a session initiation protocol (SIP).
6. The method of claim 1, wherein data contained in the packet is
identified for transmission in the first zone based on a quality of
service requirement.
7. The method of claim 1, further comprising sending information to
the mobile device to indicate the allocation of the N basic
time-frequency resource units used for the transmission of the
packet.
8. A method for a mobile device in a multi-cell wireless packet
system using a frame structure, each frame comprising a plurality
of time slots, each time slot comprising a plurality of orthogonal
frequency division multiplexing (OFDM) symbols, the method
comprising: receiving at the mobile device, from a base station,
information indicating an allocation of N basic time-frequency
resource units in a first zone of time-frequency resource
designated for transmission from a current cell, to the base
station, of packets associated with a voice application, wherein:
the first zone is selected by the base station to be different from
a second zone of time-frequency resource designated in a
neighboring cell for transmission of packets associated with the
voice application; a basic time-frequency resource unit contains a
number of subcarriers in a number of OFDM symbols; and N is an
integer number; and transmitting, to the base station, a signal
carrying a packet over the N basic time-frequency units in the
first zone.
9. The method of claim 8, wherein the packet contains data
generated from a voice source coder (vocoder).
10. The method of claim 8, further comprising receiving, from the
base station, information indicating a modulation and coding scheme
for the transmission of the packets associated with the voice
application.
11. The method of claim 8, further comprising receiving, from the
base station, information indicating transmission power control
information for the transmission of the packets associated with the
voice application.
12. A base station in a multi-cell wireless packet system using a
frame structure, each frame comprising a plurality of time slots,
each time slot comprising a plurality of orthogonal frequency
division multiplexing (OFDM) symbols, the base station comprising:
a controller configured to designate a first zone of time-frequency
resource in a cell for transmission of packets associated with a
voice application, the first zone selected to be different from a
second zone of time-frequency resource designated in a neighboring
cell for transmission of packets associated with the voice
application; a scheduler configured to allocate N basic
time-frequency resource units in the first zone for transmission of
a packet associated with the voice application to a mobile device,
wherein a basic time-frequency resource unit contains a number of
subcarriers in a number of OFDM symbols and N is an integer number;
and a transmitter configured to transmit a signal carrying the
packet to a mobile device over the N basic time-frequency units in
the first zone.
13. A mobile device in a multi-cell wireless packet system using a
frame structure, each frame comprising a plurality of time slots,
each time slot comprising a plurality of orthogonal frequency
division multiplexing (OFDM) symbols, the mobile device comprising:
a receiver configured to receive, from a base station, information
indicating an allocation of N basic time-frequency resource units
in a first zone of time-frequency resource designated for
transmission from a current cell, to the base station, of packets
associated with a voice application, wherein: the first zone is
selected to be different from a second zone of time-frequency
resource designated in a neighboring cell for transmission of
packets associated with the voice application; a basic
time-frequency resource unit contains a number of subcarriers in a
number of OFDM symbols; and N is an integer number; and a
transmitter configured to transmit, to the base station, a signal
carrying a packet over the N basic time-frequency units in the
first zone.
Description
TECHNICAL FIELD
The disclosed technology relates, in general, to wireless
communication and, in particular, to multi-carrier packet
communication networks.
BACKGROUND
Bandwidth efficiency is one of the most important system
performance factors for wireless communication systems. In packet
based data communication, where the traffic has a bursty and
irregular pattern, application payloads are typically of different
sizes and with different quality of service (QoS) requirements. In
order to accommodate different applications, a wireless
communication system should be able to provide a high degree of
flexibility. However, in order to support such flexibility,
additional overhead is usually required. For example, in a wireless
system based on the IEEE 802.16 standard ("WiMAX"), multiple packet
streams are established for each mobile station to support
different applications. At the medium access control (MAC) layer,
each packet stream is mapped into a wireless connection. The MAC
scheduler allocates wireless airlink resources to these
connections. Special scheduling messages, DL-MAP and UL-MAP, are
utilized to broadcast the scheduling decisions to the mobile
stations.
In the MAP scheduling message defined by IEEE802.16, there is
significant control overhead. For example, each connection is
identified by a 16 bits connection ID (CID). The CID is included in
the MAP message to identify the mobile station. The maximum number
of connections that a system can support is therefore 65,536. Each
mobile station has at least two management connections for control
and management messages and a various number of traffic connections
for application data traffic. As another example, each connection
includes the identification of an airlink resource that can
correspond to any time/frequency region that is allocated for
communication. The resource allocation is identified in the time
domain scale with a start symbol offset (8 bits) and a symbol
length (7 bits) and in the frequency domain scale with a start
logical subchannel offset (6 bits) and a number of allocated
subchannels (6 bits). Due to the fact that different applications
have different resource requirements, the allocated resource region
is irregular from connection to connection. As a still further
example, the modulation and coding scheme for each connection is
identified by a 4-bit MCS code, identified as either a downlink
interval usage code (DIUC) or an uplink interval usage code (UIUC).
Another 2 bits are used to indicate the coding repetition in
addition to 3 bits for power control. Overall, the overhead of a
MAP message is 52 bits. For applications such as voice-over-IP
(VoIP), the payload of an 8 Kbps voice codec is 20 bytes in every
20 ms. The overhead of the MAP message alone can therefore account
for as much as 32.5% of the overall data communication, thereby
resulting in a relatively low spectral efficiency. It would
therefore be beneficial to reduce the overhead in a multi-carrier
packet communication system to improve the spectral efficiency of
the system.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 illustrates the coverage of a wireless communication network
that is comprised of a plurality of cells.
FIG. 2 is a block diagram of a receiver and a transmitter, such as
might be used in a multi-carrier wireless communication
network.
FIG. 3 is a block diagram depicting a division of communication
capacity in a physical media resource.
FIG. 4 is a graphical depiction of the relationship between a
sampling frequency, a channel bandwidth, and usable subcarriers in
a channel.
FIG. 5 is a graphical depiction of the structure of a multi-carrier
signal in the frequency domain.
FIG. 6 is a block diagram of a time-frequency resource utilized by
a wireless communication network.
FIG. 7 is a block diagram of a classifier for classifying received
packets by application, QoS, or other factor.
FIGS. 8A and 8B are block diagrams of representative control
message formats.
FIG. 9 is a block diagram of a special resource zone with unit
sequence defined in time-first order.
FIGS. 10A-10C are block diagrams illustrating the reallocated of
resources within a resource zone.
DETAILED DESCRIPTION
A system and method for minimizing the control overhead in a
multi-carrier wireless communication network that utilizes a
time-frequency resource is disclosed. In some embodiments, one or
more zones in the time-frequency resource are designated for
particular applications, such as a zone dedicated for voice-over-IP
(VoIP) applications. By grouping applications of a similar type
together within a zone, a reduction in the number of bits necessary
for mapping a packet stream to a portion of the time-frequency
resource can be achieved. In some embodiments, modular coding
schemes associated with the packet streams may be selected that
further reduce the amount of necessary control information.
In some embodiments, packets may be classified for transmission in
accordance with application type, QoS parameters, and other
properties. An application connection-specific identifier (ACID)
may also be assigned to a packet stream. Both measures reduce the
overhead associated with managing multiple application streams in a
communication network.
In some embodiments, improved control messages may be constructed
to facilitate the control process and minimize associated overhead.
The control messages may include information such as the packet
destination, the modulation and coding method, and the airlink
resource used. Control messages of the same application type or
subtype, modulation and coding scheme, or other parameter may be
grouped together for efficiency.
While the following discussion contemplates the application of the
disclosed technology to an Orthogonal Frequency Division Multiple
Access (OFDMA) system, those skilled in the art will appreciate
that the technology can be applied to other system formats such as
Code Division Multiple Access (CDMA), Multi-Carrier Code Division
Multiple Access (MC-CDMA), or others. Without loss of generality,
OFDMA is therefore only used as an example to illustrate the
present technology. In addition, the following discussion uses
voice-over-IP as a representative application to which the
disclosed technology can be applied. The disclosed technology is
equally applicable to other applications including, but not limited
to, audio and video.
The following description provides specific details for a thorough
understanding of, and enabling description for, various embodiments
of the technology. One skilled in the art will understand that the
technology may be practiced without these details. In some
instances, well-known structures and functions have not been shown
or described in detail to avoid unnecessarily obscuring the
description of the embodiments of the technology. It is intended
that the terminology used in the description presented below be
interpreted in its broadest reasonable manner, even though it is
being used in conjunction with a detailed description of certain
embodiments of the technology. Although certain terms may be
emphasized below, any terminology intended to be interpreted in any
restricted manner will be overtly and specifically defined as such
in this Detailed Description section.
I. Wireless Communication Network
FIG. 1 is a representative diagram of a wireless communication
network 100 that services a geographic region. The geographic
region is divided into a plurality of cells 105, and wireless
coverage is provided in each cell by a base station (BS) 110. One
or more mobile devices (not shown) may be fixed or may roam within
the geographic region covered by the network. The mobile devices
are used as an interface between users and the network. Each base
station is connected to the backbone of the network, usually by a
dedicated link. A base station serves as a focal point to transmit
information to and receive information from the mobile devices
within the cell that it serves by radio signals. Note that if a
cell is divided into sectors, from a system engineering point of
view each sector can be considered as a cell. In this context, the
terms "cell" and "sector" are interchangeable.
In a wireless communication system with base stations and mobile
devices, the transmission from a base station to a mobile device is
called a downlink (DL) and the transmission from a mobile device to
a base station is called an uplink (UL). FIG. 2 is a block diagram
of a representative transmitter 200 and receiver 205 that may be
used in base stations and mobile devices to implement a wireless
communication link. The transmitter comprises a channel encoding
and modulation component 210, which applies data bit randomization,
forward error correction (FEC) encoding, interleaving, and
modulation of an input data signal. The channel encoding and
modulation component is coupled to a subchannel and symbol
construction component 215, an inverse fast Fourier transform
(IFFT) component 220, and a radio transmitter component 225. Those
skilled in the art will appreciate that these components construct
and transmit a communication signal containing the data that is
input to the transmitter 200. Other forms of transmitter may, of
course, be used depending on the requirements of the communication
network.:
The receiver 205 comprises a reception component 230, a frame and
synchronization component 235, a fast Fourier transform component
240, a frequency, timing, and channel estimation component 245, a
subchannel demodulation component 250, and a channel decoding
component 255. The channel decoding component de-interleaves,
decodes, and derandomizes a signal that is received by the
receiver. The receiver recovers data from the signal and outputs
the data for use by the mobile device or base station. Other forms
of receiver may, of course, be used depending on the requirements
of the communication network.
FIG. 3 is a block diagram depicting the division of communication
capacity in a physical media resource 300 (e.g., radio or cable)
into frequency and time domains. The frequency is divided into two
or more subchannels 305, represented in the diagram as subchannels
1, 2, . . . m. Time is divided into two or more time slots 310,
represented in the diagram as time slots 1, 2, . . . n. The
canonical division of the resource by both time and frequency
provides a high degree of flexibility and fine granularity for
resource sharing between multiple applications or multiple users of
the resource.
FIG. 4 is a block diagram representing the relationship between the
bandwidth of a given channel and the number of usable subcarriers
within that channel. A multi-carrier signal in the frequency domain
is made up of subcarriers. In FIG. 4, the sampling frequency is
represented by the variable f.sub.s, the bandwidth of the channel
is represented by the variable B.sub.ch, and the effective
bandwidth by the variable B.sub.eff (where the effective bandwidth
is a percentage of the channel bandwidth). The number of usable
subcarriers within the channel is defined by the following
equation:
.times..times..times. ##EQU00001## Where N.sub.fft is the length of
the fast Fourier transform. Those skilled in the art will
appreciate that for a given bandwidth of a spectral band or channel
(B.sub.ch), the number of usable subcarriers is finite and limited,
and depends on the size of the FFT, the sampling frequency
(f.sub.s), and the effective bandwidth (B.sub.eff) in accordance
with equation 1.
FIG. 5 is a signal diagram depicting the various subcarriers and
subchannels that are contained within a given channel. There are
three types of subcarriers: (1) data subcarriers, which carry
information data; (2) pilot subcarriers, whose phases and
amplitudes are predetermined and made known to all receivers, and
which are used for assisting system functions such as estimation of
system parameters; and (3) silent subcarriers, which have no energy
and are used for guard bands and as a DC carrier. The data
subcarriers can be arranged into groups called subchannels to
support scalability and multiple-access. The subcarriers forming
one subchannel may or may not be adjacent to each other. Each
mobile device may use some or all of the subchannels.
A multi-carrier signal in the time domain is generally made up of
time frames, time slots, and OFDM symbols. A frame consists of a
number of time slots, and each time slot is comprised of one or
more OFDM symbols. The OFDM time domain waveform is generated by
applying an inverse-fast-Fourier-transform (IFFT) to the OFDM
symbols in the frequency domain. A copy of the last portion of the
time domain waveform, known as the cyclic prefix (CP), is inserted
in the beginning of the waveform itself to form an OFDM symbol.
In some embodiments, a mapper such as the subchannel and symbol
construction component 215 in FIG. 2 is designed to map the logical
frequency/subcarrier and OFDM symbol indices seen by upper layer
facilities, such as the MAC resource scheduler or the coding and
modulation modules, to the actual physical subcarrier and OFDM
symbol indices. A contiguous time-frequency area before the mapping
may be actually discontinuous after the mapping, and vice versa. On
the other hand, in a special case, the mapping may be a "null
process", which maintains the same time and frequency indices
before and after the mapping. The mapping process may change from
time slot to time slot, from frame to frame, or from cell to cell.
Without loss of generality, the terms "resource", "airlink
resource", and "time-frequency resource" as used herein may refer
to either the time-frequency resource before such mapping or after
such mapping.
II. Airlink Resource Zones
Various technologies are now described that may be utilized in
conjunction with the wireless communication network 100 in order to
reduce the amount of control overhead associated with the use of
system resources. By reducing the control overhead, greater
spectral efficiency is achieved allowing the system to, among other
benefits, maximize the amount of simultaneously supported
communications.
FIG. 6 is a map of a time-frequency resource 600 that is allocated
for use by the wireless communication network 100. As described
above, in a typical wireless system based on the IEEE 802.16
standard ("WiMAX"), multiple packet streams are established for
each mobile device to support different applications. At the medium
access control (MAC) layer, each packet stream is mapped into a
wireless connection. As a result, various applications carried in
packet streams may be spread throughout the available
time-frequency resource. To overcome the inefficiencies associated
with maintaining this mapping, FIG. 6 depicts an alternative way of
managing multiple packet streams. The time-frequency resource 600
may be divided into one or more zones 605a, 605b, . . . 605n. Each
of the zones 605a, 605b, . . . 605n is associated with a particular
type of application. For example, zone 605a may be associated with
voice applications (e.g., VoIP), zone 605b may be associated with
video applications, and so on. As will be described in additional
detail below, by grouping like applications together the amount of
control overhead in MAC headers is reduced. Zones may be
dynamically allocated, modified, or terminated by the system.
When applications of a similar type are grouped together within a
zone, a reduction in the number of bits necessary for mapping a
packet stream to a time-frequency segment can be achieved. In some
embodiments, the identification of the time-frequency segment
associated with a particular packet stream can be indicated by the
starting time-frequency coordinate and the ending time-frequency
coordinate relative to the starting point of the zone. The
granularity in the time coordinates can be one or multiple OFDM
symbols, and that in the frequency coordinates can be one or
multiple subcarriers. If the time-frequency resource is divided
into two or more zones, the amount of control information necessary
to map to a location relative to the starting point of the zone may
be significantly less than the amount of information necessary to
map to an arbitrary starting and ending coordinate in the entire
time-frequency resource.
Within each zone 605a, 605b, . . . 605n, the time-frequency
resource may be further divided in accordance with certain rules to
accommodate multiple packet streams V.sub.1, V.sub.2, . . .
V.sub.m. For example, as depicted in FIG. 6, zone 605a is divided
into multiple columns and the packet streams are arranged from top
down in each column and from left to right across the columns. The
width of each column can be a certain number of subcarriers. Each
packet stream V.sub.1, V.sub.2, . . . V.sub.m may be associated
with an application. For example, V.sub.1 is the resource segment
to be used for the first voice packet stream, V.sub.2 is the
resource segment to be used for the second voice packet stream,
etc. While the zone 605a is divided and the packet streams numbered
starting at an origin of the zone, it will be appreciated that the
division of the time-frequency resource in accordance with certain
rules may start at other origin locations within the zone as well.
Segments within each zone may be dynamically allocated by the
system as requested and released by the system when expressly or
automatically terminated.
When the zones are further subdivided into time-frequency segments
in accordance with certain rules, a mapping of packet streams to
segment may be achieved using a one-dimensional offset with respect
to the origin of the zone rather than the two-dimensional (i.e.
starting time-frequency coordinate and ending time-frequency
coordinate relative to the starting point of the zone) mapping
method discussed above. Calculation of such an offset may require
knowledge of a modulation and coding scheme that is associated with
a particular packet stream. For example, Table 1 below sets forth
representative modulation and forward-error correction (FEC) coding
schemes (MCS) that may be used for voice packet streams under
various channel conditions.
TABLE-US-00001 TABLE 1 Coding Raw MCSI Modulation rate Information
bits symbols Units 1 16QAM 1/2 160 80 1 2 QPSK 1/2 160 160 2 3 QPSK
1/4 160 320 4 4 QPSK 1/8 160 640 8
In some embodiments, the MCS may be selected to utilize modular
resources. For example, as illustrated in Table 1, 80 raw
modulation symbols are needed to transmit 160 information bits
using 16QAM modulation and rate-1/2 coding, the highest available
MCS in the table. The resource utilized by this highest MCS is
called a basic resource unit ("Unit"), i.e., 80 raw symbols in this
example. The resource utilized by other MCS is simply an integer
multiple of the basic unit. For example, four units are required to
transmit the same number of information bits using QPSK modulation
with rate-1/4 coding. The MCS index (MCSI) conveys the information
about modulation and coding schemes. For a known vocoder, MCSI also
implies the number of AMC resource units required for a voice
packet. Those skilled in the art will appreciate that coding and
signal repetition can be combined to provide lower coding rates.
For example, rate-1/8 coding can be realized by a concatenation of
rate-1/2 coding and 4-time repetition.
The decision process for selecting the proper MCS of a packet can
vary by application. In some embodiments, the process for voice
packets can be more conservative than that for general data packets
due to the QoS requirements of the voice applications. For example,
when the signal to interference noise ratio (SINR) is used as a
threshold for selecting the MCS, the threshold value for voice
packets is set higher than that for general data packets. For
example, the SINR threshold of QPSK with rate-1/2 coding for voice
packets is 12 dB, while that for general data packets is 10 dB.
If a MCS from Table 1 is selected for each packet stream contained
in a particular zone, the offset to a segment representing a
particular packet stream may be easily calculated. For example, an
index VZI.sub.1, VZI.sub.2, . . . VZI.sub.m is shown at the origin
of each segment that is contained in the zone 605a. The index for
any selected packet stream is defined as the sum of all basic
resource units associated with each packet stream preceding the
selected packet stream, with an optional adjustment depending on
the location where the division of the time-frequency resource is
started (typically no adjustment is required since the division
starts at the origin of the zone). For example, the location index
for the first voice packet stream is VZI.sub.1=0 since it starts at
the origin of the zone 605a. The first packet stream has an MCS of
1, which implies that one basic resource unit is used. As a result,
the index for the second voice packet stream is VZI.sub.2=1. The
second packet stream has an MCS of 4, which implies that eight
basic resource units are used. As a result, the index for the third
voice packet stream is VZI.sub.3=9, arrived by summing the basic
resource units used for the preceding first and second packet
streams.
Using basic resource units as the granularity of a location offset
to the packet packet stream reduces the number of bits required to
represent its location with the zone 605a. For example, to support
a maximum of 64 VoIP calls in a cell, a maximum of 64.times.8=512
units might be used, assuming that every voice packet is
transmitted using the lowest MCS. Therefore, a 9-bit number is
sufficient to represent a VZI. In practice, different voice packets
may be transmitted using different MCSs, some with MCSI=1, some
with MCSI=4, so on so forth. According to statistics, a shorter
bit-length than the maximum needed, for example 8 bits, may be used
for VZI for practical purpose.
In some embodiments, control information necessary to map a packet
stream to a resource segment may be still further reduced. In the
case where an MCS is used with packet streams that are located
sequentially in the zone. the index of a packet can be inferred
from the MCSI of the packets located before the subject packet. For
example, if the first voice packet stream uses MCSI.sub.1=1, 16QAM
with 1/2 coding, and the second voice packet stream uses
MCSI.sub.2=4, QPSK with 1/8 coding, then the first two voice packet
streams occupy 1+8=9 units, and the starting location of the third
voice packet stream is the 9th unit. Rather than encode the index
for each packet stream in the control information, the index can be
omitted in the control message and the offset from the origin of
the zone calculated as necessary.
Allocation of the time-frequency resource 600 can be carried out in
a variety of ways. In some embodiments, an application zone may
contain all subcarriers of one or multiple OFDM symbols or time
slots. In some embodiments, the definition of an application zone,
such as the location and size of the zone, may be different from
cell-to-cell 105. In some embodiments, in order to avoid inter-cell
interference the zones of similar applications are allocated at
different locations in neighboring cells. For example, voice
applications may be located at a lower frequency range in the
time-frequency resource in one cell, and at a higher frequency
range in the time-frequency range in an adjacent cell. In some
embodiments, the system allocates a fixed amount of resource to
each voice connection. The system uses AMC and matches it with
adaptive multi-rate (AMR) voice coding to improve the voice
quality. Moreover, unused resources in one application zone may be
allocated for other applications.
In a system with one or multiple application zones, the remaining
resource unused by the application zones can be treated as a
special resource zone. The special resource zone may be irregular
in shape. For example, FIG. 9 depicts a time-frequency resource 900
having three defined zones 905, 910, and 915. The remaining
resource area that is shaded in the figure represents the special
resource zone. The MAC scheduler may track the time-frequency
resources in this special zone and broadcast the resource
allocation in a special zone MAP message. In some embodiments, the
special zone MAP message explicitly identifies the resource zone,
for example using the time and frequency coordinates of a resource
block. A mobile device can identify its own resource by decoding
the MAP message.
In some embodiments, both the base station and the mobile device
share the configuration information of the special resource zone,
and view the special zone as a contiguous resource zone. The MAP
message only includes the resource allocation information in the
special resource zone, using connection ID (described below),
resource identification parameters and MCS index.
In some embodiments, the MAP message can be further compressed if
the special resource zone is further divided into a sequence of
pre-defined resource units. For example, the shaded area in FIG. 9
has been further divided into forty-two resource units 920, first
numbered sequentially along the time axis and then continuing in
columns along the frequency axis. If the size of each resource unit
is pre-defined, the location within the special resource zone may
be determined based on a mapping to a sequence number.
III. Application Connection IDs
When a mobile device enters a wireless network, it is first
assigned a basic connection identification (BCID) for each
direction of the wireless connection: downlink and uplink. A BCID
can be used for control messages or generic (unclassified)
application connections. The BCID for downlink may or may not be
the same as that of the uplink.
In some embodiments, a classification of packet streams may be
performed by the system. FIG. 7 is a block diagram of a system
component 700 for receiving IP packets and sorting the received
packets into various streams. The system component 700 includes a
classifier 705 having associated classification rules 710. The
classifier receives incoming packets, each packet having various
header information such as an Ethernet header 715, an IP header
720, a UDP header 725, an RTP header 730 and an RTP payload 735.
The packets are classified by the classifier 705 and output into
different application data queues 740 where they will subsequently
be transmitted by an OFDMA transmitter 745.
The classifier 705 is able to classify the packets based on
application type, quality of service (QoS) requirement, or other
properties. For example, packets from a voice application stream
are identified based on a special value in the type of service
(ToS) field in the IP header 720 of the packets. A new combination
of RTP/UDP/IP headers with the special IP ToS field value indicates
a new voice application stream. Such a new stream is identified by
peeking into voice session setup protocol messages, such as session
initiation protocol (SIP). The classification performed by the
classifier is based on one or more classification rules 710. The
classification rules can be configured statically or dynamically by
a control process. Each classification rule is defined using
parameters, such as application type, QoS parameters, and other
properties that may be determined from the received packets.
In some embodiments, the incoming packets may also be assigned an
application connection-specific identifier (ACID) in addition to or
in lieu of a BCID. Each ACID can be assigned to a corresponding
packet stream. For example, an ACID can be assigned to voice
packets that together make up a voice application. When an ACID is
assigned to a voice application, the ACID may also be referred to
as a voice connection ID (VCID). As another example, an ACID can be
assigned to a packet stream that requires a particular QoS.
Furthermore, an application packet stream can be further classified
into different sub-types, based on certain properties of that
application. For example, voice applications can be further
classified into different sub-types based on the voice source
coding (vocoder) methods (e.g., G.711 and G.729A). When further
classified in this matter, the sub-types may each be assigned their
own ACID. For certain multi-casting applications, an ACID may also
be shared by multiple base stations or mobile devices.
Once established, the connection IDs, including BCIDs and ACIDs,
are disseminated, through broadcasting messages for example, to the
corresponding base station(s) and mobile device(s) for proper
packet transmission and reception. As was previously discussed, the
medium access control (MAC) scheduler may allocate specific zones
of airlink resources for certain types of packet streams.
A connection ID is released once the wireless system determines
that there is no need to continue the connection. For example, a
voice connection and its VCID are released once the system detects
deactivation of the voice stream. In some embodiments, the voice
connection is deactivated if the voice session disconnect is
detected through snooping SIP signaling. In some embodiments, the
voice connection is released if there is no voice packet activity
on the connection for a certain period of time.
In some embodiments, the same bit length is used in different types
of connections IDs, including BCIDs and ACIDs. In some embodiments,
different types of connection IDs may have different bit lengths.
For example, in a typical implementation for voice applications, a
BCID may be 16-bits to accommodate a large number of mobile devices
and unclassified applications, while a VCID is 6-bits to
accommodate up to 64 simultaneous voice connections in a cell. A
shorter ACID length is beneficial for reducing control overhead,
especially when an application utilizes many small data packets,
such as VoIP packets.
In some embodiments, an ACID is further augmented by other
properties of the utilized airlink resources, such as time or
frequency indices, to identify an application connection. This can
be used to further reduce ACID bit length or to increase the
maximum number of accommodated application connections given a
certain ACID bit length. For example, a voice codec generates voice
application data periodically. The allocation period is usually a
multiple of the airlink frame duration. In this case, the airlink
frame number can be combined with a VCID to identify a voice
connection. For example, the voice codec of G.723.1 generates a
voice frame once every 30 milliseconds. The MAC scheduler allocates
airlink resource to such a voice connection once every 30 ms. In a
wireless cellular system using 5 ms frame duration, a single VCID
can be shared by 6 voice streams, each associated with a different
frame number to uniquely identify a voice connection.
IV. Control Messages
When airlink resource zones or application-specific IDs are
utilized by the system, various improved control messages, often
called Information Elements (IEs), may be constructed to facilitate
the control process and minimize the control overhead. Various
control message improvements are described herein.
In some embodiments, the IE is sent prior to transmitting an
application packet to indicate information associated with the
packet, such as the packet destination, the modulation and coding
method, and the airlink resource used. For example, the IE for a
voice packet may include the VCID (indicative of the packet
destination), the MCSI (encoding scheme), and the VZI (index to
location of the packet stream within the airlink resource). In some
embodiments, the VCID is 6 bits, the MCSI is 2 bits, and the VZI is
8 bits, thereby resulting in a 2-byte IE overhead for each voice
packet. Alternatively, the IE for a voice packet may include only
the VCID and the MCSI, with the VZI inferred from the MCSIs of
previous packet streams in the airlink resource as described above.
When using only the VCID and MCSI, the IE overhead for each voice
packet is reduced to only 1 byte. Additional control information,
such as power control information, can be added to the IE with
additional bit fields. The reduction in control bits improves the
overall bandwidth efficiency of the wireless communication
network.
In some embodiments, a base station sends the IE before a downlink
packet to inform the mobile device for proper reception of the
packet, and the base station sends the IE before an uplink packet
to inform the mobile device for proper transmission of the packet.
The downlink and uplink packet IEs may be separately grouped
together. The IEs may be broadcasted or multi-casted to
corresponding destinations.
In some embodiments, the IEs of the same application type or
subtype may be grouped together. A special field, called an
Application MAP (AMAP) subheader, for a specific application type,
may be added to the IE. The subheader may indicate the application
type and the length of the IE group. FIG. 8A is a block diagram of
a representative IE 800 with an AMAP subheader 805, in this case
used for voice applications. The AMAP subheader 805 includes a type
variable and a length variable. As depicted in FIG. 8A, type=01
indicates that the application type is voice. Length=3 indicates
that the subheader is followed by three voice IEs. The remainder of
the IE contains the three voice IEs 810a, 810b, and 810c. For
example, if the AMAP subheader was associated with streams in the
zone 605a depicted in FIG. 6, then voice IE 810a would pertain to
packet stream V.sub.1, voice IE 810b would pertain to packet stream
V.sub.2, and voice IE 810c would pertain to packet stream V.sub.3.
Those skilled in the art will appreciate that the although text is
used to indicate the contents of the IE in FIG. 8A, in an actual
implementation the text would be replaced by appropriately coded
information.
In some embodiments, the IEs for all packets that are transmitted
with the same modulation and coding schemes (MCS) are grouped
together for efficiency. FIG. 8B is a block diagram of a block 850
of IEs that are grouped by MCS. A frame control header (FCH) 855 or
other control message is transmitted prior to the block to indicate
the length and the MCS used for each segment of the block. In some
embodiments, adaptive modulation and coding (AMC) is used for the
transmission of the IE's. A special rule, which is known to both
base stations and mobile devices, can be used to determine the IE
MCS, based on the MCS of its corresponding packet for proper
reception of the IE. In some embodiments, the MCS for an IE is
maintained the same as that of its corresponding application
packet. In some embodiments, the MCS for an IE is one level more
conservative than that of its corresponding packet. For example, if
the MCSI for a packet is 2 (QPSK with rate-1/2 coding), then the
MCSI for its IE is 3 (QPSK with rate-1/4coding).
V. Voice Activity Detection
Typical voice conversations contain approximately 50 percent
silence. In order to take advantage of the fact that about half of
the time data does not need to be transmitted at the same rate as
when a user is speaking, the system may rely upon detecting the
period of silence and reducing the effective data transfer rate
during that period. The silence period in conversation is detected
by a vocoder using technologies such as Voice Activity Detection
(VAD). Voice packets are only generated when voice activity is
detected. During the silence period, the voice packet data rate is
greatly reduced.
In addition to reducing the voice packet data rate during periods
of silence, the bandwidth allocation for the voice connection may
also be reduced. The MAC scheduler at the base station may use the
indication of voice activity to adjust the bandwidth allocation for
the voice connection. In the uplink direction, the mobile device
sends a special MAC message once a VAD indication is received from
its vocoder. The MAC message indicates to the base station that the
voice data rate is being temporarily reduced. When such an
indication is received, the MAC scheduler can reduce the airlink
resource allocated to the voice connection. Similarly, if the VAD
indicates new voice activity, the mobile device notifies the base
station using a MAC message and the original resource allocation is
re-applied to the voice connection.
In the downlink direction, if there is no voice packet to be
transmitted over a voice connection, the MAC scheduler allocates
the resource to other voice connections. As a consequence, a
resource block previous allocated for the connection in a
particular zone may become vacant. Several methods can be used to
deal with such fragmentation in the zone.
In some embodiments, the MAC scheduler at the base station
reallocates the resource with the objective of minimizing the
impact to other voice connections, such as their adaptive
modulation and coding processes.
In some embodiments, the MAC scheduler maintains the resource
allocation of the other voice connections, and allocates the
resource vacated by the silent voice connection to new voice
connections or other application packets.
In some embodiments, the MAC scheduler moves all the subsequent
allocations up to fill the resource gap. As shown in FIG. 10A, once
a voice connection, identified by VCID 2 enters a silent period,
the other voice connections are moved by the MAC scheduler to
occupy the resource vacated by VCID 2.
In some embodiments, the MAC scheduler uses the last voice
time-frequency resource in the same zone to fill the resource gap
of a silent voice connection. FIG. 10B illustrates such a case,
when the MAC scheduler moves the last voice connection VCID 12 to
occupy the resource allocation gap that is vacated by the voice
connection VCID 2.
In some embodiments, the MAC scheduler uses the last voice
time-frequency resource that has the same coding and modulation
scheme, and is contained in the same zone, to fill the resource
gap. The resource gap that is introduced by such a replacement is
then filled by the voice time-frequency resource that is subsequent
to the voice time-frequency resource that was moved. As shown in
FIG. 10C, voice connection VCID 6 uses the same coding and
modulation scheme as voice connection VCID 2, and is the last
connection having that scheme in the zone. When voice connection
VCID 2 goes into a silent period, the MAC scheduler allocates the
voice connection VCID 2 resource to voice connection VCID 6. The
MAC scheduler then moves resources after voice connection VCID 6,
specifically VCID 7 in FIG. 10C, to occupy the resource allocation
gap that is caused by moving voice connection VCID 6.
The above detailed description of embodiments of the system is not
intended to be exhaustive or to limit the system to the precise
form disclosed above. While specific embodiments of, and examples
for, the system are described above for illustrative purposes,
various equivalent modifications are possible within the scope of
the system, as those skilled in the relevant art will recognize.
For example, while processes are presented in a given order,
alternative embodiments may perform routines having steps in a
different order, and some processes may be deleted, moved, added,
subdivided, combined, and/or modified to provide alternative or
subcombinations. Each of these processes may be implemented in a
variety of different ways. Further any specific numbers noted
herein are only examples: alternative implementations may employ
differing values or ranges.
These and other changes can be made to the invention in light of
the above Detailed Description. While the above description
describes certain embodiments of the technology, and describes the
best mode contemplated, no matter how detailed the above appears in
text, the invention can be practiced in many ways. Details of the
system may vary considerably in its implementation details, while
still being encompassed by the technology disclosed herein. As
noted above, particular terminology used when describing certain
features or aspects of the technology should not be taken to imply
that the terminology is being redefined herein to be restricted to
any specific characteristics, features, or aspects of the
technology with which that terminology is associated. In general,
the terms used in the following claims should not be construed to
limit the invention to the specific embodiments disclosed in the
specification, unless the above Detailed Description section
explicitly defines such terms. Accordingly, the actual scope of the
invention encompasses not only the disclosed embodiments, but also
all equivalent ways of practicing or implementing the invention
under the claims.
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